%{ /* Written by Pace Willisson (pace@blitz.com) * and placed in the public domain. * * Largely rewritten by J.T. Conklin (jtc@wimsey.com) * * $FreeBSD$ */ #include #include #include #include #include #include #include #include #include #include #include #include /* * POSIX specifies a specific error code for syntax errors. We exit * with this code for all errors. */ #define ERR_EXIT 2 enum valtype { integer, numeric_string, string } ; struct val { enum valtype type; union { char *s; intmax_t i; } u; } ; struct val *result; int chk_div(intmax_t, intmax_t); int chk_minus(intmax_t, intmax_t, intmax_t); int chk_plus(intmax_t, intmax_t, intmax_t); int chk_times(intmax_t, intmax_t, intmax_t); void free_value(struct val *); int is_zero_or_null(struct val *); int isstring(struct val *); struct val *make_integer(intmax_t); struct val *make_str(const char *); struct val *op_and(struct val *, struct val *); struct val *op_colon(struct val *, struct val *); struct val *op_div(struct val *, struct val *); struct val *op_eq(struct val *, struct val *); struct val *op_ge(struct val *, struct val *); struct val *op_gt(struct val *, struct val *); struct val *op_le(struct val *, struct val *); struct val *op_lt(struct val *, struct val *); struct val *op_minus(struct val *, struct val *); struct val *op_ne(struct val *, struct val *); struct val *op_or(struct val *, struct val *); struct val *op_plus(struct val *, struct val *); struct val *op_rem(struct val *, struct val *); struct val *op_times(struct val *, struct val *); intmax_t to_integer(struct val *); void to_string(struct val *); int yyerror(const char *); int yylex(void); int yyparse(void); char **av; %} %union { struct val *val; } %left '|' %left '&' %left '=' '>' '<' GE LE NE %left '+' '-' %left '*' '/' '%' %left ':' %token TOKEN %type start expr %% start: expr { result = $$; } expr: TOKEN | '(' expr ')' { $$ = $2; } | expr '|' expr { $$ = op_or ($1, $3); } | expr '&' expr { $$ = op_and ($1, $3); } | expr '=' expr { $$ = op_eq ($1, $3); } | expr '>' expr { $$ = op_gt ($1, $3); } | expr '<' expr { $$ = op_lt ($1, $3); } | expr GE expr { $$ = op_ge ($1, $3); } | expr LE expr { $$ = op_le ($1, $3); } | expr NE expr { $$ = op_ne ($1, $3); } | expr '+' expr { $$ = op_plus ($1, $3); } | expr '-' expr { $$ = op_minus ($1, $3); } | expr '*' expr { $$ = op_times ($1, $3); } | expr '/' expr { $$ = op_div ($1, $3); } | expr '%' expr { $$ = op_rem ($1, $3); } | expr ':' expr { $$ = op_colon ($1, $3); } ; %% struct val * make_integer(intmax_t i) { struct val *vp; vp = (struct val *) malloc (sizeof (*vp)); if (vp == NULL) { errx(ERR_EXIT, "malloc() failed"); } vp->type = integer; vp->u.i = i; return vp; } struct val * make_str(const char *s) { struct val *vp; char *ep; vp = (struct val *) malloc (sizeof (*vp)); if (vp == NULL || ((vp->u.s = strdup (s)) == NULL)) { errx(ERR_EXIT, "malloc() failed"); } /* * Previously we tried to scan the string to see if it ``looked like'' * an integer (erroneously, as it happened). Let strtoimax() do the * dirty work. We could cache the value, except that we are using * a union and need to preserve the original string form until we * are certain that it is not needed. * * IEEE Std.1003.1-2001 says: * /integer/ An argument consisting only of an (optional) unary minus * followed by digits. * * This means that arguments which consist of digits followed by * non-digits MUST NOT be considered integers. strtoimax() will * figure this out for us. */ (void)strtoimax(s, &ep, 10); if (*ep != '\0') vp->type = string; else vp->type = numeric_string; return vp; } void free_value(struct val *vp) { if (vp->type == string || vp->type == numeric_string) free (vp->u.s); } intmax_t to_integer(struct val *vp) { intmax_t i; if (vp->type == integer) return 1; if (vp->type == string) return 0; /* vp->type == numeric_string, make it numeric */ errno = 0; i = strtoimax(vp->u.s, (char **)NULL, 10); if (errno == ERANGE) err(ERR_EXIT, NULL); free (vp->u.s); vp->u.i = i; vp->type = integer; return 1; } void to_string(struct val *vp) { char *tmp; if (vp->type == string || vp->type == numeric_string) return; /* * log_10(x) ~= 0.3 * log_2(x). Rounding up gives the number * of digits; add one each for the sign and terminating null * character, respectively. */ #define NDIGITS(x) (3 * (sizeof(x) * CHAR_BIT) / 10 + 1 + 1 + 1) tmp = malloc(NDIGITS(vp->u.i)); if (tmp == NULL) errx(ERR_EXIT, "malloc() failed"); sprintf(tmp, "%jd", vp->u.i); vp->type = string; vp->u.s = tmp; } int isstring(struct val *vp) { /* only TRUE if this string is not a valid integer */ return (vp->type == string); } int yylex(void) { char *p; if (*av == NULL) return (0); p = *av++; if (strlen (p) == 1) { if (strchr ("|&=<>+-*/%:()", *p)) return (*p); } else if (strlen (p) == 2 && p[1] == '=') { switch (*p) { case '>': return (GE); case '<': return (LE); case '!': return (NE); } } yylval.val = make_str (p); return (TOKEN); } int is_zero_or_null(struct val *vp) { if (vp->type == integer) { return (vp->u.i == 0); } else { return (*vp->u.s == 0 || (to_integer (vp) && vp->u.i == 0)); } /* NOTREACHED */ } int main(int argc, char *argv[]) { int c; setlocale (LC_ALL, ""); if (getenv("EXPR_COMPAT") != NULL) { av = argv + 1; } else { while ((c = getopt(argc, argv, "")) != -1) switch (c) { default: fprintf(stderr,"usage: expr [--] expression\n"); exit(ERR_EXIT); } av = argv + optind; } yyparse(); if (result->type == integer) printf("%jd\n", result->u.i); else printf("%s\n", result->u.s); return (is_zero_or_null(result)); } int yyerror(const char *s __unused) { errx(ERR_EXIT, "syntax error"); } struct val * op_or(struct val *a, struct val *b) { if (is_zero_or_null (a)) { free_value (a); return (b); } else { free_value (b); return (a); } } struct val * op_and(struct val *a, struct val *b) { if (is_zero_or_null (a) || is_zero_or_null (b)) { free_value (a); free_value (b); return (make_integer ((intmax_t)0)); } else { free_value (b); return (a); } } struct val * op_eq(struct val *a, struct val *b) { struct val *r; if (isstring (a) || isstring (b)) { to_string (a); to_string (b); r = make_integer ((intmax_t)(strcoll (a->u.s, b->u.s) == 0)); } else { (void)to_integer(a); (void)to_integer(b); r = make_integer ((intmax_t)(a->u.i == b->u.i)); } free_value (a); free_value (b); return r; } struct val * op_gt(struct val *a, struct val *b) { struct val *r; if (isstring (a) || isstring (b)) { to_string (a); to_string (b); r = make_integer ((intmax_t)(strcoll (a->u.s, b->u.s) > 0)); } else { (void)to_integer(a); (void)to_integer(b); r = make_integer ((intmax_t)(a->u.i > b->u.i)); } free_value (a); free_value (b); return r; } struct val * op_lt(struct val *a, struct val *b) { struct val *r; if (isstring (a) || isstring (b)) { to_string (a); to_string (b); r = make_integer ((intmax_t)(strcoll (a->u.s, b->u.s) < 0)); } else { (void)to_integer(a); (void)to_integer(b); r = make_integer ((intmax_t)(a->u.i < b->u.i)); } free_value (a); free_value (b); return r; } struct val * op_ge(struct val *a, struct val *b) { struct val *r; if (isstring (a) || isstring (b)) { to_string (a); to_string (b); r = make_integer ((intmax_t)(strcoll (a->u.s, b->u.s) >= 0)); } else { (void)to_integer(a); (void)to_integer(b); r = make_integer ((intmax_t)(a->u.i >= b->u.i)); } free_value (a); free_value (b); return r; } struct val * op_le(struct val *a, struct val *b) { struct val *r; if (isstring (a) || isstring (b)) { to_string (a); to_string (b); r = make_integer ((intmax_t)(strcoll (a->u.s, b->u.s) <= 0)); } else { (void)to_integer(a); (void)to_integer(b); r = make_integer ((intmax_t)(a->u.i <= b->u.i)); } free_value (a); free_value (b); return r; } struct val * op_ne(struct val *a, struct val *b) { struct val *r; if (isstring (a) || isstring (b)) { to_string (a); to_string (b); r = make_integer ((intmax_t)(strcoll (a->u.s, b->u.s) != 0)); } else { (void)to_integer(a); (void)to_integer(b); r = make_integer ((intmax_t)(a->u.i != b->u.i)); } free_value (a); free_value (b); return r; } int chk_plus(intmax_t a, intmax_t b, intmax_t r) { /* sum of two positive numbers must be positive */ if (a > 0 && b > 0 && r <= 0) return 1; /* sum of two negative numbers must be negative */ if (a < 0 && b < 0 && r >= 0) return 1; /* all other cases are OK */ return 0; } struct val * op_plus(struct val *a, struct val *b) { struct val *r; if (!to_integer (a) || !to_integer (b)) { errx(ERR_EXIT, "non-numeric argument"); } r = make_integer (/*(intmax_t)*/(a->u.i + b->u.i)); if (chk_plus (a->u.i, b->u.i, r->u.i)) { errx(ERR_EXIT, "overflow"); } free_value (a); free_value (b); return r; } int chk_minus(intmax_t a, intmax_t b, intmax_t r) { /* special case subtraction of INTMAX_MIN */ if (b == INTMAX_MIN) { if (a >= 0) return 1; else return 0; } /* this is allowed for b != INTMAX_MIN */ return chk_plus (a, -b, r); } struct val * op_minus(struct val *a, struct val *b) { struct val *r; if (!to_integer (a) || !to_integer (b)) { errx(ERR_EXIT, "non-numeric argument"); } r = make_integer (/*(intmax_t)*/(a->u.i - b->u.i)); if (chk_minus (a->u.i, b->u.i, r->u.i)) { errx(ERR_EXIT, "overflow"); } free_value (a); free_value (b); return r; } int chk_times(intmax_t a, intmax_t b, intmax_t r) { /* special case: first operand is 0, no overflow possible */ if (a == 0) return 0; /* cerify that result of division matches second operand */ if (r / a != b) return 1; return 0; } struct val * op_times(struct val *a, struct val *b) { struct val *r; if (!to_integer (a) || !to_integer (b)) { errx(ERR_EXIT, "non-numeric argument"); } r = make_integer (/*(intmax_t)*/(a->u.i * b->u.i)); if (chk_times (a->u.i, b->u.i, r->u.i)) { errx(ERR_EXIT, "overflow"); } free_value (a); free_value (b); return (r); } int chk_div(intmax_t a, intmax_t b) { /* div by zero has been taken care of before */ /* only INTMAX_MIN / -1 causes overflow */ if (a == INTMAX_MIN && b == -1) return 1; /* everything else is OK */ return 0; } struct val * op_div(struct val *a, struct val *b) { struct val *r; if (!to_integer (a) || !to_integer (b)) { errx(ERR_EXIT, "non-numeric argument"); } if (b->u.i == 0) { errx(ERR_EXIT, "division by zero"); } r = make_integer (/*(intmax_t)*/(a->u.i / b->u.i)); if (chk_div (a->u.i, b->u.i)) { errx(ERR_EXIT, "overflow"); } free_value (a); free_value (b); return r; } struct val * op_rem(struct val *a, struct val *b) { struct val *r; if (!to_integer (a) || !to_integer (b)) { errx(ERR_EXIT, "non-numeric argument"); } if (b->u.i == 0) { errx(ERR_EXIT, "division by zero"); } r = make_integer (/*(intmax_t)*/(a->u.i % b->u.i)); /* chk_rem necessary ??? */ free_value (a); free_value (b); return r; } struct val * op_colon(struct val *a, struct val *b) { regex_t rp; regmatch_t rm[2]; char errbuf[256]; int eval; struct val *v; /* coerce to both arguments to strings */ to_string(a); to_string(b); /* compile regular expression */ if ((eval = regcomp (&rp, b->u.s, 0)) != 0) { regerror (eval, &rp, errbuf, sizeof(errbuf)); errx(ERR_EXIT, "%s", errbuf); } /* compare string against pattern */ /* remember that patterns are anchored to the beginning of the line */ if (regexec(&rp, a->u.s, (size_t)2, rm, 0) == 0 && rm[0].rm_so == 0) { if (rm[1].rm_so >= 0) { *(a->u.s + rm[1].rm_eo) = '\0'; v = make_str (a->u.s + rm[1].rm_so); } else { v = make_integer ((intmax_t)(rm[0].rm_eo - rm[0].rm_so)); } } else { if (rp.re_nsub == 0) { v = make_integer ((intmax_t)0); } else { v = make_str (""); } } /* free arguments and pattern buffer */ free_value (a); free_value (b); regfree (&rp); return v; }